The Regulation of Segmentation Clock Period in Zebrafish

Herrgen, Leah

08 December 2008

Oscillations are present at many different levels of biological organization. The cell cycle that directs the division of individual cells, the regular depolarization of neurons in the sinu-atrial node which underlies the regular beating of the heart, the circadian rhythms that govern the daily activity cycles of virtually all organisms, and the clocks that make entire populations of fireflies flash on and off in unison feature as prominent examples of biological clocks. During development, biological clocks regulate the patterning of growing tissues, as is the case in vertebrate somitogenesis, and potentially also in vertebrate limb outgrowth and axial segmentation of invertebrate embryos. During vertebrate segmentation, the embryonic axis is subdivided along its anterior-posterior axis into epithelial spheres of cells called somites. This rhythmic process is thought to be driven by a multicellular oscillatory gene network, the so-called segmentation clock. Oscillations of hairy and enhancer of split gene products have been proposed to constitute the core clockwork in individual cells, and these oscillators are coupled to each other by Delta-Notch intercellular signaling. The interaction of the segmentation clock with a posteriorly-moving arrest wavefront then translates the temporal information encoded by the clock into a spatial pattern of segments. In the framework of this Clock and Wavefront model, segment length is determined by both clock period and arrest wavefront velocity. How the period of the segmentation clock is regulated is presently unknown, and understanding the mechanism of period setting might yield insight into the nature and function of the segmentation clock. In this study, two different but complementary approaches were pursued to investigate how period is regulated in the zebrafish segmentation clock. First, it has been reported that zebrafish mind bomb (mib) mutant embryos form somites more slowly than their wt siblings, suggesting that Mib might be implicated in period setting. Mib is an E3 ubiquitin ligase required for ubiquitination and endocytosis of the Notch ligand Delta, and Notch signaling is impaired in mutants with defective Mib. It has been suggested that the mechanistic basis for the requirement of Delta endocytosis in Notch signaling is a need for Delta to enter a particular endocytic compartment, potentially a recycling endosome, in a ubiquitin-dependent manner, where its signaling ability might be established or amplified by an as yet unknown posttranslational modification. In the present study, Delta trafficking through the endocytic pathway was analyzed in the PSM of wt and mib embryos through colocalization studies with endocytic markers. The rationale of this approach was that if Delta gained access to a particular endocytic compartment through Mib-dependent endocytosis, the presence of Delta in this compartment would be expected to be reduced in mutants with defective Mib, thereby revealing the compartment’s identity. However, no qualitative changes in colocalization with different endocytic markers could be detected in mib mutants, and the methods available did not allow for quantification of colocalization in wt or mutant backgrounds. However, Delta colocalized with 13 markers of recycling endosomes, consistent with the hypothesis that these are functionally important in Notch signaling. More refined techniques will be necessary for a quantitative analysis of normal as compared to impaired Delta trafficking. A genetic approach to period regulation proved to be successful for the Drosophila circadian clock, where the identification of period mutants advanced the understanding of the clock’s genetic circuitry. This motivated a screen for period mutants of the segmentation clock, which was carried out by measuring somitogenesis period, segment length and arrest wavefront velocity in a pool of candidate mutants. A subset of Delta-Notch mutants, and embryos treated with a small-molecule inhibitor that impairs Notch signaling, displayed correlated increases in somitogenesis period and segment length, while there was no detectable change in arrest wavefront velocity. Combined, these findings suggested that segmentation clock period is increased in experimental conditions with impaired Delta-Notch signaling. Using a theoretical description of the segmentation clock as an array of coupled phase oscillators, the delay in the coupling and the autonomous frequency of individual cells were estimated from the direction and magnitude of the period changes. The mutants presented here are the first candidates for segmentation clock period mutants in any vertebrate. The nature of the molecular lesions in these mutants, all of which affect genes implicated in intercellular Delta-Notch signaling, suggests that communication between oscillating PSM cells is a key factor responsible for setting the period of the segmentation clock.

zebrafish

segmentation

somitogenesis

oscillator

clock

Delta

Notch

delayed coupling

Zebrafisch

Segmentation

Somitogenesis

Oszillator

Delta

Notch

Kopplung

ddc:570

rvk:WG 2100

Intracellular signaling cascades in the dopaminergic specification of fetal mesencephalic neural progenitor cells.

Meyer, Anne K.

19 June 2009

Neural stem (progenitor) cells (NPCs) from fetal tissue are an ideal transplantable cell source. They divide rapidly, are able to generate cells of all three neural lineages and do not divide uncontrolled once transplanted into a host organism. To obtain large quantities of cells for transplantation strategies and to eliminate primary cell contaminations, long periods of in vitro cultivation are necessary. Mouse NPCs are a crucial tool for further investigations of neural stem cells because they make the employment of transgenic animals in vivo and cells in vitro possible. So far only short-term expanded fetal mouse NPCs have been shown to generate dopaminergic neurons and it is not clear whether this was due to differentiation or a result of increased survival of primary dopaminergic neurons. The aims of the thesis were to characterize mouse fetal NPCs, to establish the long-term expansion of fetal mouse NPCs and the generation of dopaminergic neurons in long-term expanded fetal mouse NPCs, to investigate the signaling mechanisms involved in the differentiation of mouse fetal NPCs towards the dopaminergic phenotype and to compare short and long-term expanded NPCs. Long-term expanded fetal mesencephalic NPCs could be grown under suspension and adherent culture conditions and showed self- renewing capacity as well as markers typical for NPCs. They could be differentiated into the three major cell types of the nervous system, but suspension NPCs had a larger potential to generate neurons than adherently grown NPCs. Signaling cascades involved in this process were p38 and Erk1/2 mediated. Long-term expanded NPCs did not have the potential to generate neuronal sub-types. Importantly, they did not generate dopaminergic neurons. Mouse fetal NPCs from three different developmental stages (E10, E12, and E14) were employed but were not able to differentiate into dopaminergic neurons using factors known to stimulate in vitro dopaminergic specification. When cultivated in vitro for short periods, fetal mesencephalic NPCs were able to generate dopaminergic neurons. By eliminating all primary Th- positive neurons, FACS-sorting of NPCs proved a de novo generation of dopaminergic neurons, because after cultivation and differentiation of Th- depleted cell solutions dopaminergic neurons were present in the culture. However, these newly generated neurons failed to incorporate BrdU, making a generation without cell division from precursors probable. The precursor population of short cultures differed from long-term expanded cultures suggesting an ‘aging’ effect of in vitro conditions. IL-1 was a potent inducer of the dopaminergic neuronal phenotype in short-term expanded in vitro cultures and was expressed in vitro as well as in vivo at E14. Several important conclusions concerning fetal mouse stem cell behavior could be drawn from the results of this work: Firstly, the results showed for the first time that in fetal mouse mesencephalic NPCs dopaminergic neurons differentiate from precursors without cell division, therefore consuming those progenitors. Therein fetal mouse NPCs differ significantly from rat and human NPCs or respond differently to the same in vitro conditions that need to be optimized for fetal mouse NPCs. Secondly, less committed precursors find appropriate conditions to proliferate but not to generate the more committed DA precursors that are able to generate dopaminergic neurons. The hallmarks of stem cells, self-renewal and multipotentiality, seem to be part of a delicate balance, that, when unsettled, goes in favor of one side without the possibility of returning to the previous status. Further research should focus on two coherent issues: the isolation of more pure populations of progenitors and the more precise characterization of progenitor populations to find out which in vitro conditions need to be provided to keep the balance between proliferation and differentiation potential. The knowledge gained about stem cells this way would help establish cell sources for transplantation strategies. / Stammzellen sind ein wichtiges Werkzeug für regenerative Therapien im Bereich der neurodegenerativen Erkrankungen wie der Parkinson’schen Erkrankung. Ein besonderer Vorteil von Stammzellen gegenüber dem bereits zur Transplantation verwendeten Primärgewebe, ist ihre Fähigkeit zur fortlaufenden Zellteilung, so dass ausreichende Mengen zur Transplantation zur Verfügung stehen. Der Vorteil von fetalen neuralen Stammzellen (fNSZ) ist ihre genomische Stabilität, die dazu führt, dass bei Transplantationen keine Tumore entstehen. Dennoch ist der Großteil ihrer Eigenschaften und Potentiale noch unbekannt und die optimalen Wachstumsbedingungen für eine lange in vitro Kultur und optimale Differenzierung in dopaminerge Neuronen müssen erforscht werden, um bessere Transplantate herzustellen. Insbesondere Stammzellen der Maus sind für die Forschung von immenser Wichtigkeit, da sie die Arbeit mit transgenen Tieren ermöglichen. Die Zielsetzungen dieser Arbeit waren die Charakterisierung der fNSZ der Maus, die Langzeitexpansion und die anschließende Differenzierung in dopaminerge Neurone. Die Signalkaskaden der frühen Differenzierung und die Unterschiede von kurz- und langzeitkultivierten Stammzellen wurden untersucht. Es konnte gezeigt werden, dass fNSZ der Maus nach Langzeitkultivierung in alle Zelltypen des zentralen Nervensystems, also Neuronen und Glia differenzieren und die dabei aktivierten Signalkaskaden p38 und Erk1/2 vermittelt sind. Das Differenzierungspotential zu neuronalen Subtypen (also auch zu dopaminergen Nervenzellen) verloren diese fetalen Stammzellen unter Kulturbedingungen schnell. Das steht im Gegensatz zu fetalen Stammzellen aus Ratte oder dem Menschen, die auch nach langer Kultivierung ihr dopaminerge Potential erhalten. Nur nach Kurzzeitkultivierung waren dopaminerge Neurone nachzuweisen, die jedoch nicht durch Zellteilung aus Vorläuferzellen hervorgegangen waren. Die Eliminierung aller primären Neurone aus der Mittelhirnisolation durch FACS-sorting von Th-Gfp transgenen Mäusen bewies die de novo Generation der dopaminergen Neurone aus Vorläuferzellen ohne Zellteilung während der Kultivierung der Stammzellen. Diese Ergebnisse zeigten, dass in fetalen mesenzephalen NSZ der Maus dopaminerge Neurone von spezialisierten Vorläuferzellen differenzieren, wodurch diese der Kultur verloren gehen. Weniger spezialisierte Vorläuferzellen finden Bedingungen, die ihre Kultivierung ermöglichen, sind aber nicht in der Lage, spezifischere Vorläuferzellen zu bilden. Die Markenzeichen von Stammzellen, Selbsterneuerung (durch Zellteilung) und das Potential, die Zelltypen des Nervensystems zu generieren, scheinen fein balancierte Zustände zu sein, die bei einer Störung nicht wiederherzustellen sind. Die Ergebnisse dieses Projektes sind von großer Bedeutung für die Forschung zur Zellersatztherapie der Parkinson’schen Erkrankung, deren ultimatives Ziel es ist, eine sichere und verlässlich expandierbare Zellquelle zu etablieren, die fähig ist, in dopaminerge Neurone zu differenzieren. Solche Stammzellen würden Bemühungen um Transplantationsstrategien für neurodegenerative Erkrankungen unterstützen und vorantreiben.

Neural stem cells

dopaminergic

fetal

mouse

differentiation

Neurale Stammzellen

dopaminerge

fetal

Maus

Differenzierung

ddc:570

rvk:WG 2100

The Role of Cdep in the Embryonic Morphogenesis of Drosophila melanogaster

Morbach, Anne

27 July 2016

Many organs and structures formed during the embryonic morphogenesis of animals derive from epithelia. Epithelia are made up of apicobasally polarized cells which adhere to and communicate with each other, allowing for epithelial integrity and plasticity. During embryonic morphogenesis, epithelia change their shape and migrate in a coordinated manner. How these epithelial processes are regulated is still not fully understood. In a forward genetic screen using the embryo of the fruit fly Drosophila melanogaster, candidate genes influencing the morphogenesis of epithelial structures were identified. Three genes, CG17364, CG17362 and CG9040 were identified as possible regulators of lumen stability in the salivary glands, tubular organs deriving from the embryonic epithelium. Furthermore, the gene Cdep was found to play a crucial role in epithelial sheet migration during dorsal closure of the embryo. Embryos carrying genomic insertions that could affect the expression of CG17364, CG17362 and CG9040 show a luminal penotype of the embryonic salivary glands characterized by alternating bloated and seemingly closed sections. Therefore, one of these genes or a combination of them likely plays a role in stabilizing the salivary gland lumen. However, neither CG17364 nor CG17362 or CG9040 contain any known protein domains, hence their molecular roles remain unknown. Cdep (Chondrocyte-derived ezrin-like protein) is a member of the FERM-FA subclass of proteins. Proteins of the FERM family have been shown to interact with the plasma membrane and membrane-bound proteins as well as cytoskeleton components. Accordingly, they have been implicated in stabilizing the cell cortex, and some of them are involved in signal transduction mechanisms. In addition to a FERM domain, Cdep also contains a RhoGEF domain, although is still not clear whether it actually exerts GEF activity. Genomic insertions in the Cdep locus cause defects in embryonic dorsal closure and atypical migratory behaviour in epithelial tubes. In order to study the molecular role of Cdep, the CRISPR/Cas9 system was employed to establish loss-of-function mutants of Cdep. The mutants show aberrations in germ band retraction, dorsal closure and head involution. Moreover, I found that two mutants carrying a premature STOP codon in the Cdep ORF, CdepE16X and CdepG17X, rescue the defects observed in embryonic cuticles mutant for two other FERM-FA members yurt (yrt) and coracle (cora). A deletion of the full Cdep ORF did not rescue those defects. I hypothesize that CdepE16X and CdepG17X encode Cdep variants with increased activity, which compensates for the loss of yrt or cora function, respectively. In conclusion, this leads to a model in which Cdep acts in parallel to Yrt and Cora during Drosophila embryonic morphogenesis. Many of the defects described in this study are reminiscent of phenotypes found in embryos mutant for components and downstream effectors of the Jun-N-terminal Kinase (JNK) pathway. Hence, my work supports an earlier hypothesis according to which a mouse homologue of Cdep, Farp2, acts as an upstream activator of the JNK pathway during epithelial cell migration in vitro (Miyamoto et al., 2003) The data provided here shows that Cdep plays a role in the morphogenesis of a great number of epithelia-derived organs and structures in vivo. My study therefore elucidates a missing link between cell migration cues and JNK pathway activation.

Drosophila

Cdep

Embryogenese

Entwicklungsbiologie

Genetik

JNK

Drosophila

Embryogenesism

Development

genetics

JNK

ddc:570

rvk:WG 2100

Drosophila

Cdep

Embryogenese

Entwicklungsbiologie

Genetik

JNK

Studying the Patterning Mechanisms and Cell Fates during Limb Regeneration in Ambystoma mexicanum

Kragl, Martin

15 January 2008

We studied patterning mechanisms and cell fates during limb regeneration in the axolotl. 1) It is crucial to understand the earliest events of patterning. Since it is technically challenging to study early events, we established single cell PCR. This new tool will allow us to obtain novel insight into the initial steps of limb patterning. 2)We have examined the roles of different tissues regarding their fates and features of proximo- distal patterning. Our strategy was to transplant GFP+ skin, skeleton, muscle and Schwann cells from transgenic donors to limbs of wild type hosts, amputate through the graft and analyze fluorescent progeny combined with the use of molecular markers. Our results revealed that different subpopulations of blastema cells exist regarding two aspects. First, we found that progeny of skin and skeleton have some tissue specific memory since they did not give rise to muscle lineages. However, cells of the skin contributed to other mesenchymal tissues like cartilage or tendons, while the majority of skeleton- derived cells undergoes self- renewal. Second, we performed one cellular and two molecular assays to investigate what tissues generate cells that exhibit features of proximo- distal patterning. Both assays revealed that Schwann cell- derived progeny do not display such features while progeny of skin, skeleton and muscle did. Therefore, we conclude that the blastema is a heterogeneous mix of cells regarding tissue lineages and features of proximo- distal patterning.

axolotl

limb regeneration

blastema

skin

skeleton

Axolotl

Gliedmassenregeneration

Blastema

Haut

Skelett

Muskel

Schwannzellen

HoxA13

Meis

Myf5

Pax7

MHCI

ddc:570

rvk:WG 2100

Regulation of Mitotic Spindle Assembly in Caenorhabditis elegans Embryos / Regulation der Bildung der mitotischen Spindel in Caenorhabditis elegans embryos

Schlaitz, Anne-Lore

10 June 2007

The mitotic spindle is a bipolar microtubule-based structure that mediates proper cell division by segregating the genetic material and by positioning the cytokinesis cleavage plane. Spindle assembly is a complex process, involving the modulation of microtubule dynamics, microtubule focusing at spindle poles and the formation of stable microtubule attachments to chromosomes. The cellular events leading to spindle formation are highly regulated, and mitotic kinases have been implicated in many aspects of this process. However, little is known about their counteracting phosphatases. A screen for genes required for early embryonic cell divisions in C. elegans identified rsa-1 (for regulator of spindle assembly 1), a putative Protein Phosphatase 2A (PP2A) regulatory subunit whose silencing causes defects in spindle formation. Upon rsa-1(RNAi), spindle poles collapse onto each other and microtubule amounts are strongly reduced. My thesis work demonstrates that RSA-1 indeed functions as a PP2A regulatory subunit. RSA-1 associates with the PP2A enzyme and recruits it to centrosomes. The centrosome binding of PP2A furthermore requires the new protein RSA-2 as well as the core centrosomal protein SPD-5 and is based on a hierarchical protein-protein interaction pathway. When PP2A is lacking at centrosomes after rsa-1(RNAi), the centrosomal amounts of two critical mitotic effectors, the microtubule destabilizer KLP-7 and the kinetochore microtubule stabilizer TPXL-1, are altered. KLP-7 is increased, which may account for the reduction of microtubule outgrowth from centrosomes in rsa-1(RNAi) embryos. TPXL-1 is lost from centrosomes, which may explain why spindle poles collapse in the absence of RSA-1. TPXL-1 physically associates with RSA-1 and RSA-2, suggesting that it is a direct target of PP2A. In summary, this work defines the role of a novel PP2A complex in mitotic spindle assembly and suggests a model for how different microtubule re-organization steps might be coordinated during spindle formation.

mitosis

spindle assembly

protein phosphatase 2A

centrosome

microtubule

Caenorhabditis elegans embryo

Mitose

mitotische Spindel

Protein Phosphatase 2A

Centrosom

Mikrotubulus

Caenorhabditis elegans Embryo

ddc:570

rvk:WG 2100

Mechanism of cell adhesion at the midbrain-hindbrain neural plate in the teleost Danio rerio

Kadner, Diana

30 July 2009

The correct development of multicellular organisms is tightly regulated by intrinsic and extrinsic factors at specific time points. Disturbance on any level of these multiple processes may result in drastic phenotypes or eventually death of the organism. The midbrain-hindbrain boundary (also termed isthmic organizer) is a region of high interest as well in early as also in later development. The isthmic region carries organizer identity by the expression and subsequent release of FGF8. False patterning events of this region in early developmental stages would therefore display dramatic results over time. As it has been shown that the midbrain-hindbrain boundary (mhb) in the zebrafish is a compartment (or lineage restriction) boundary I tried to understand the underlying molecular mechanism for its correct establishment. In this work I focused both on embryological, molecular and genetic means to characterize involved molecules and mechanisms. In the first part of the thesis I followed in vivo cell transplantation assays, having started with an unbiased one. Cells of either side the mhb were challenged with this boundary by bringing them into direct cell contact with their ectopic counterpart. In a biased approach, cells overexpressing mRNA of specific candidate genes were transplanted and their clonal distribution in host embryos was analyzed. In the second part of the thesis I started interfering with specific candidate genes by transiently knocking down their protein translation. The adhesion molecules of the Eph/ephrin class had been shown to restrict cell mixing and thereby creating compartment boundaries in other tissues, such as the hindbrain, in the zebrafish and other organisms. Additionally, we generated several stable genetic mutant lines in cooperation with the Tilling facility at the Max-Planck-Institute. The only acquired potential null mutant ephrinB2bhu2971 was analyzed and characterized further. I observed that a knock down or knock out of only one of the ephrinB2 ligands does not seem to be sufficient for a loss of compartment boundary formation. The combinatory approach of blocking translation of EphrinB2a in ephrinB2bhu2971 mutants gave very complex and interesting phenotypes, which need to be investigated further.

midbrain-hindbrain boundary

MHB/isthmic organizer

zebrafish

Tilling

Eph/ephrin

Mittel-Hinterhirngrenze

MHB/Isthmus

Zebrafisch

Tilling

Eph/ephrin

ddc:570

rvk:WG 2100

Mechanical cell properties in germ layer progenitor migration during zebrafish gastrulation / Mechanische Eigenschaften der Keimblatt-Vorläuferzellen während der Migration in der Zebrafisch-Gastrulation

Arboleda-Estudillo, Yoana

07 April 2010

Gastrulation leads to the formation of the embryonic germ layers, ectoderm, mesoderm and endoderm, and is the first key morphogenetic process that occurs in development. Gastrulation provides a unique developmental assay system in which to study cellular movements and rearrangements in vivo. The different cell movements occurring during gastrulation take place in a highly coordinated spatial and temporal manner, indicating that they must be controlled by a complex interplay of morphogenetic and inductive events. Generally, cell movement constitutes a highly integrated program of different cellular behaviors including sensing, polarization, cytoskeletal reorganization, and changes in adhesion and cell shape. During migration, these different behaviors require a continuous regulation and feedback control to direct and coordinate them. In this work, we analyze the cellular and molecular mechanisms underlying the different types of cell behaviors during gastrulation in zebrafish. Specifically, we focus on the role of the adhesive and mechanical properties of germ layer progenitors in the regulation of gastrulation movements. In the first part of the project, we investigated the role of the adhesive and mechanical properties of the different germ layer progenitor cell types for germ layer separation and stratification. In the second part of this study, we applied the same methodology to determine the function of germ layer progenitor cell adhesion in collective cell migration. Tissue organization is thought to depend on the adhesive and mechanical properties of the constituent cells. However, it has been difficult to determine the precise contribution of these different properties due to the lack of tools to measure them. Here we use atomic force microscopy (AFM) to quantify the adhesive and mechanical properties of the different germ layer progenitor cell types. Applying this methodology, we demonstrate that mesoderm and endoderm progenitors are more adhesive than ectoderm cells and that E-cadherin is the main adhesion molecule regulating this differential adhesion. In contrast, ectoderm progenitors exhibit a higher actomyosin-dependent cell cortex tension than mesoderm and endoderm progenitors. Combining these data with tissue self-assembly in vitro and in vivo, we provide evidence that the combinatorial activities of cell adhesion and cell cortex tension direct germ layer separation and stratification. It has been hypothesized that the directionality of cell movement during collective migration results from a collective property. Using a single cell transplantation assay, we show that individual progenitor cells are capable of normal directed migration when moving as single cells, but require cell-cell adhesion to participate in coordinated and directed migration when moving collectively. These findings contribute to the understanding of the gastrulation process. Cell-cell adhesion is required for collective germ layer progenitor cell migration, and cell cortex tension is critical for germ layer separation and stratification. However, many questions still have to be solved. Future studies will have to explore the interaction between the adhesive and mechanical progenitor cell properties, as well as the role of these properties for cell protrusion formation, cell polarization, interaction with extracellular matrix, and their regulation by different signaling pathways.

zebrafish

gastrulation

germ layer progenitor cell migration

adhesion

tension

E-cadherin

myosin

Nodal

Zebrafisch

Gastrulation

Keimblattvorläuferzellen-Migration

Adhäsion

Zelloberflächenspannung

E-cadherin

Myosin

Nodal

ddc:570

rvk:WG 2100

Self-assembly and Structure Investigation of Recombinant S-layer Proteins Expressed in Yeast for Nanobiotechnological Applications

Korkmaz, Nuriye

24 January 2011

In numerous Gram-negative and Gram-positive bacteria as well as in Archaea SL proteins form the outermost layer of the cell envelope. SL (glyco)monomers self-assemble with oblique (p2), tetragonal (p4), or hexagonal (p3, p6) symmetries [12]. SL subunits interact with each other and with the underlying cell surface by relatively weak non-covalent forces such as hydrogen-bonds, ionic bonds, salt-bridges or hydrophobic interactions. This makes them easy to isolate by applying chaotropic agents like urea and guanidine hydrochloride (GuHCl), chelating chemicals, or by changing the pH of the environment [10]. Upon dialysis in an ambient buffer monomers recrystallize into regular arrays that possess the forms of flat sheets, open ended cylinders, or spheres on solid substrates, at air-water intefaces and on lipid films, making them appealing for nanobiotechnological applications [3, 18]. The aim of this study was to investigate the structure, thermal stability, in vivo self-assembly process, recrystallization and metallization of three different recombinant SL proteins (SslA-eGFP, mSbsC-eGFP and S13240-eGFP) expressed in yeast S. cerevisiae BY4741 which could be further used in nanobiotechnological applications. In order to fulfill this aim, I investigated the in vivo expression of SL proteins (SslA, SbsC, S13240) tagged with eGFP (SL-eGFP) in the yeast S. cerevisiae BY4141. First, I characterized the heterologous expression of SL fusion constructs with growth and fluorescence measurements combined with Western blot analyses. Fluorescence microscopy investigations of overnight grown cultures showed that SslA-eGFP fusion protein was expressed as fluorescent patches, mSbsC-eGFP as tubular networks, and S13240-eGFP as hollow-like fibrillar network structures, while eGFP did not show any distinct structure Thermal stability of in vivo expressed SL-eGFP fusion proteins were investigated by fluorescence microscopy and immunodetection. In vivo self-assembly kinetics during mitosis and meiosis was the second main issue. In parallel, association of in vivo mSbsC-eGFP structures with the cellular components was of interest. A network of tubular structures in the cytosol of the transformed yeast cells that did not colocalize with microtubules or the actin cytoskeleton was observed. Time-resolved analysis of the formation of these structures during vegetative growth and sporulation was investigated by live fluorescence microscopy. While in meiosis ascospores seemed to receive assembled structures from the diploid cells, during mitosis surface layer structures were formed de novo in the buds. Surface layer assembly always started with the appearance of a dot-like structure in the cytoplasm, suggesting a single nucleation point. In order to get these in vivo SL assemblies stably outside the cells (in situ), cell distruption experiments were conducted. The tubular structures formed by the protein in vivo were retained upon bursting the cells by osmotic shock; however their average length was decreased. During dialysis, monomers obtained by treatment with chaotropic agents recrystallized again to form tube-like structures. This process was strictly dependent on calcium ions, with an optimal concentration of 10 mM. Further increase of the Ca2+ concentration resulted in multiple non-productive nucleation points. It was further shown that the lengths of the S-layer assemblies increased with time and could be controlled by pH. After 48 hours the average length at pH 9.0 was 4.13 µm compared to 2.69 µm at pH 5.5. Successful chemical deposition of platinum indicates the potential of recrystallized mSbsC-eGFP structures for nanobiotechnological applications. For example, such metalized protein nanotubes could be used in conductive nanocircuit technologies as nanowires.

S-Schicht

eGFP

Hefe

Fluoreszenzmikroskopie

Rekristallisation

Metallisierung

Nanobiotechnologie

S-layer

eGFP

Yeast

Fluorescence microscopy

Recrystallization

Metallization

Nanobiotechnology

ddc:570

rvk:WG 2100

Hairy switches and oscillators - reconstructing the zebrafish segmentation clock

Oswald, Annelie

26 May 2014

Formation of segments during vertebrate embryogenesis is regulated by a biological clock. Models and experimental data indicate that the core of this clock consists of a cell- autonomous single cell oscillator. This oscillator likely involves a genetic feedback loop of transcriptional repressors belonging to the hairy gene family. In zebrafish, three her genes, her1, hes6 and her7, have been identified as core oscillator components. The main purpose of this project was to study the molecular mechanism of the hairy gene negative feedback oscillator in single cells. To determine whether a single cell oscillator is part of the zebrafish segmentation clock, a cell dissociation protocol was established to track the expression of Her1 ex vivo. Upon dissociation, Her1 expression continued to oscillate for up to three cycles. The period of oscillations was significantly slower than that of the segmentation clock, but appears to speed up in the presence of serum. To test whether the hairy gene interactions are sufficient to generate oscillations in single cells, a protocol was established that uses synthetic biology principles to design, construct and characterize hairy gene networks in yeast. First a library of network parts, containing hairy genes, promoters and Her binding sites was generated and subsequently assembled into simple devices to test their functionality in yeast. The three core oscillator components, Her1, Hes6 and Her7, were characterized and optimized for expression in yeast. In the SWITCH-OFF assay, the Her1 protein, modified with a MigED yeast repressor domain, was found to function as a transcriptional repressor in yeast, while Hes6 with the same modification can not. The dissociation of segmentation clock cells provides the first direct evidence that single cell oscillators exist in zebrafish. In this system, oscillator dynamics can be studied without the interactions of higher level clock components. In parallel, establishing a yeast chassis for hairy gene networks provides a novel technique to directly test predicted oscillator mechanisms by constructing them ’bottom up’.

Hairy gene

Oszillator

Synthetische Biologie

Zebrafish

Hefe

Zellen

hairy genes

oscillator

synthetic biology

zebrafish

yeast

single cells

ddc:570

rvk:WG 2100

Entwicklung eines FISH-Referenzkaryotyps der Zuckerrübe (Beta vulgaris) für die Integration genetischer Kopplungskarten und die Analyse der chromosomalen Verteilung von repetitiven Sequenzen

Päsold, Susanne

13 January 2014

Die Verbindung von genetischen, physikalischen und zytologischen Daten ist entscheidend für die Genom- und Chromosomenanalyse. Obwohl Beta vulgaris (2n = 18) als wichtige Kulturpflanze und Untersuchungsobjekt der Grundlagenforschung eine intensiv analysierte Art darstellt, existiert bisher keine Verknüpfung zwischen Kopplungsgruppen (LG) und Chromosomen. B.-vulgaris-Chromosomen können zudem aufgrund fehlender morphologischer Unterscheidungsmerkmale bisher nicht einzeln identifiziert und klassifiziert werden. Somit sind zytogenetisch gewonnene Ergebnisse nicht ohne weiteres auf genetische Kopplungsgruppen und physikalische Karten übertragbar. Zytogenetische Methoden können zur Analyse struktureller Chromosomenveränderungen, zur Identifizierung und Lokalisierung von repetitiver DNA sowie zur Kartierung schwierig zu positionierender Marker verwendet werden. Ziel dieser Arbeit war es daher, ein FISH (Fluoreszenz-in-situ-Hybridisierung)-Verfahren zu etablieren, das die Kopplungsgruppen und Chromosomen der Zuckerrübe korreliert und die mikroskopische Identifizierung aller Chromosomenarme ermöglicht. Im Rahmen dieser Arbeit wurde ein FISH-Referenzkaryotyp der Zuckerrübe entwickelt. Durch ein Sondenset aus 18 BACs (bacterial artificial chromosome) sind alle Chromosomenarme der Zuckerrübe identifizierbar und werden mit den nördlichen und südlichen Enden der genetischen Kopplungsgruppen verknüpft. Somit ist eine einheitliche Nummerierung von Kopplungsgruppen und Chromosomen möglich. Durch die gleichzeitige Hybridisierung von chromosomenspezifischen BACs und den Satelliten-DNA-Sonden pAv34 und pBV VI beziehungsweise pEV und pBV wurden die Verteilungsmuster der Sequenzfamilien auf den Chromosomen ermittelt. Die gleichzeitige Hybridisierung aller vier repetitiven Sonden ergab ein chromosomenspezifisches Muster aus subtelomerischen, interkalaren und zentromerischen Signalen. Damit ist die Identifizierung aller B.-vulgaris-Chromosomen in einem einzelnen FISH-Experiment möglich. Zudem wurden dadurch die Chromosomen mit hohem Anteil an tandemartig angeordneten repetitiven Sequenzen identifiziert und die Chromosomenregionen lokalisiert, welche die Sequenzassemblierung behindern können. Sowohl das entwickelte BAC-Set als auch der Sondenpool aus repetitiver DNA unterscheiden die somatischen Metaphasechromosomen erstmals unabhängig von trisomen Linien. Da mit Hilfe der Satelliten-DNA-Sonden alle Chromosomen gleichzeitig markiert werden können, waren die spezifischen physikalischen Längen ermittelbar. Sie wurden mit den genetischen Längen der Kopplungsgruppen in Verbindung gebracht und deckten eine kopplungs-gruppenspezifische Rekombinationshäufigkeit zwischen 0,73 und 1,14 Mb/cM auf. Durch Hybridisierung der BACs und subtelomerischer beziehungsweise telomerischer Sonden auf Pachytänchromosomen wurde der Abstand der BACs sowie der in ihnen enthaltenen genetischen Marker zum physikalischen Chromosomenende abgeschätzt. An fünf Chromo-somenenden wurde ein deutlicher Abstand zwischen den Signalen des BACs und der terminalen Sonden festgestellt. Die zugehörigen Kopplungsgruppen sind demnach erweiterbar. Zudem wurden drei BACs mit nicht detektierbarem Abstand zum Chromosomenende durch FISH an gestreckten Chromatinfasern näher untersucht. Einer der drei BACs wurde eindeutig in unmittelbarer Nähe des Telomers nachgewiesen. Für dieses Ende (Chr 2N) ist die Wahrscheinlichkeit gering, dass die Kopplungsgruppe durch zusätzliche Marker erweitert werden kann; sie wird darum als abgeschlossen angesehen. Für die Enden Chr 4S und Chr 9S war der Abstand zwischen BAC und terminaler Sonde zu groß, um ihn durch Fiber-FISH zu ermitteln. Für sie sind weitere distal zu positionierende Marker wahrscheinlich. Weiterhin wurden bioinformatische Analysen an der verfügbaren B.-vulgaris-Genomsequenz RefBeet 1.0 durchgeführt. Scaffolds, welche die genetischen terminalen Marker enthalten, wurden bioinformatisch identifiziert und auf ihren Gehalt subtelomerischer und telomerischer Sequenzen untersucht. Vorhandene terminale Sequenzen sind ein Nachweis für eine terminale Lokalisierung der in-silico-Chromosomenabschnitte. Für drei Scaffolds mit zuvor ungeklärter Lage wurde dadurch das in-silico-Chromosom ermittelt beziehungsweise die nördliche oder südliche Position auf dem Chromosom dargestellt. Durch die Lokalisierung dieser Bereiche innerhalb der Sequenz in Bezug zum genetischen Marker und unter Berücksichtigung der Ergebnisse der Pachytän-FISH wurde die Strangorientierung von 16 Scaffolds ermittelt. Auf 14 Scaffolds wurden die Abstände der Marker zu den terminalen Sequenzen bestimmt. Der Median betrug etwa 196 kb. Für alle Kopplungsgruppenenden außer dem Norden von LG 2 und LG 4 ist das Vorhandensein weiterer distaler genetischer Marker wahrscheinlich. Satelliten-DNA ist innerhalb einer Art meist homogen, kann jedoch chromosomenspezifische Varianten ausbilden. Auf dem BAC-Marker für Chr 2N wurde durch Southern-Hybridisierung die subtelomerische Sequenzfamilie pAv34 detektiert. Von dem betreffenden BAC wurde eine Subklonbank erstellt. Durch Southern-Hybridisierung wurde der pAv34-Gehalt der Subklone analysiert. Positive Klone wurden sequenziert. Dabei wurden vier verschiedene vollständige pAv34-2N-Monomere detektiert. Im Vergleich mit pAv34-Volllängenmotiven aus der RefBeet 1.0 und dem Datensatz der nicht assemblierten Sequenzen der RefBeet 0.2 bilden die pAv34-2N-Einheiten mit pAv34-Kopien, die verschiedenen in-silico-Chromosomen und Contigs zugeordnet sind, eine Subfamilie. Aus den Sequenzen der Subklone wurden zwei Subklon-Contigs gebildet, die im in-silico-Chromosomenabschnitt von Chr 2N (Bvchr2.un.sca001) positioniert wurden. Dadurch wurden Regionen bisher unbekannter Sequenz entschlüsselt. Abweichungen zwischen den assemblierten Daten und den Subklonsequenzen deuten auf Assemblierungsfehler der Genomsequenz in repetitiven Bereichen hin. Die in dieser Arbeit erzielten Ergebnisse ermöglichen erstmalig die eindeutige Identifizierung aller B.-vulgaris-Chromosomen unabhängig vom Zellzyklusstadium und im Einklang mit genetischen Informationen. Zytogenetische sind jetzt mit molekularen Daten integrierbar und können verwendet werden, um den chromosomenspezifischen Satelliten-DNA-Gehalt aufzudecken und mögliche chromosomenspezifische Subfamilien zu identifizieren. Sie erlauben, physikalische Abstände zwischen Markern zu ermitteln und die Abdeckung von Kopplungsgruppen im terminalen Bereich zu untersuchen. Die Ergebnisse tragen dazu bei, Marker und nicht zugeordnete Contigs und Scaffolds zu kartieren, Ursachen für Lücken aufzudecken und damit die Sequenzdaten des Zuckerrübengenoms zu einer fortlaufenden, hochqualitativen Sequenz zu assemblieren. Die zytogenetischen Daten bilden zudem die Basis für zukünftige Untersuchungen struktureller Umbauten von Chromosomen, die während der Genomevolution stattfanden. / The correlation of genetic, physical and cytological data is crucial for interdisciplinary genome and chromosome analyses. Beta vulgaris (2n = 18) is an important crop and an object of basic research. Although it is an intensely analysed species, its genetic linkage groups (LG) have not been assigned to chromosomes. Additionally, sugar beet chromosomes lack distinct morphological features and could therefore not be identified and classified individually. Consequently, results generated by cytogenetic methods can not be readily applied to genetic and physical maps. Cytogenetic approaches enable analysing structural chromosomal changes, identifying and localizing repetitive DNA, and mapping of markers which are difficult to place within linkage maps. Therefore, the main objective of this work has been the development of a FISH (fluorescence in situ hybridization) procedure that correlates LGs with chromosomes of sugar beet and that allows the microscopic identification of individual chromosome arms. In this work a FISH reference karyotype for sugar beet has been established. A set of 18 BACs (bacterial artificial chromosome) allows the unequivocal identification of each sugar beet chromosome and assigns them to the southern and northern ends of LGs. Hence, the chromosomes are numbered in accordance with the genetic map. The arm-specific BACs and the satellite DNA families pBV and pBV VI or pEV and pAv34 have been hybridized simultaneously to assign the distribution patterns of the highly abundant sequence families to chromosomes. Simultaneous hybridization of the four repetitive probes revealed a chromosome-specific pattern of subtelomeric, intercalary and centromeric signals. Thus, each of the sugar beet chromosomes can be identified in a single FISH experiment. Furthermore, chromosomes with a high content of repetitive DNA have been identified and chromosomal regions that may hinder the correct sequence assembly have been localized. The BAC set as well as the pooled satellite DNA probes discriminate the somatic chromosomes for the first time independently from trisomic lines. Since the chromosomes are differentially labelled with the satellite DNA probes their physical distances could be determined and correlated with genetic distances of the corresponding LGs. A LG-specific recombination frequency from 0.73 to 1.14 Mb/cM has been disclosed. BACs and subtelomeric or telomeric sequences have been hybridized simultaneously on pachytene chromosomes to estimate distances between BACs plus the markers they contain and the physical chromosome ends. Five BACs showed substantial distances to the physical chromosome ends; the corresponding LGs could thus be extended by additional markers. Furthermore, three BACs showing only minor distances to chromosome ends have been investigated in detail by fiber-FISH. One of these BACs was localized closely adjacent to the telomere. For this chromosome end (Chr 2N) it is unlikely that the LG could be extended distally by additional markers and is therefore considered to be closed. The BACs for the chromosome ends Chr 4S and Chr 9S have been too distant from the terminal probe to be bridged by fiber-FISH. For them it is likely that further markers can be placed distally. Furthermore, the B. vulgaris genomic sequence RefBeet 1.0 has been investigated. Scaffolds containing terminal genetic markers have been identified bioinformatically and analysed for the content of subtelomeric and telomeric sequences. The occurrence of terminal sequences confirms the terminal localization of in silico chromosome segments. Three scaffolds with an initially unknown position could thus be allocated to in silico chromosomes and to the northern or southern position on the chromosome. The strand orientation of 16 scaffolds has been determined based on the localization of terminal sequences in relation to the genetic marker considering the results of FISH on pachytene chromosomes. The distance between markers and terminal sequences has been determined for 14 scaffolds. The median is 196 kb. It is likely that further markers can be placed distally from all LG ends except for the north of LG 2 and LG 4. Satellite DNA is usually homogenous within one species; however, it can form chromosome-specific variants. Southern hybridization revealed that the BAC marker for Chr 2N contains the subtelomeric sequence family pAv34. The BAC has been subcloned and the pAv34 content of the subclones has been analysed by Southern hybridization. Positive clones have been sequenced. Thereby, four pAv34-2N monomeres have been detected. Compared to full-length pAv34 motives derived from the RefBeet 1.0 and from unassembled sequence data of the RefBeet 0.2 the pAv34-2N units form a subfamily together with pAv34 copies assigned to different in silico chromosomes and contigs. The subclone sequences have been assembled to two subclone contigs, which have been positioned within the in silico chromosome segment of Chr 2N (Bvchr2.un.sca001). Thereby, regions of unknown sequence have been decoded and probable misassemblies in repetitive regions within the RefBeet 1.0 have been disclosed. The results obtained in this work enable the identification of all sugar beet chromosomes independently from their stage of cell division and in accordance with genetic information. Cytogenetic data are integrated with molecular data and can be used for identifying the chromosome-specific distribution of repeats and chromosome-specific repeat variants. They enable determining physical distances between markers and investigating the terminal coverage of LGs. The results support the correct mapping of markers and unassigned contigs, uncover reasons for gaps within maps and sequence assemblies, and thus contribute to assembling data into a continuous high quality genome sequence of sugar beet. Moreover, the cytogenetic data represent the basis for future investigations of structural chromosomal changes that took place during evolution.

Karyotyp

FISH

BACs

Pachytänchromosomen

Satelliten-DNA

Zuckerrübe

Beta vulgaris

karyotype

FISH

BACs

pachytene chromosomes

satellite DNA

sugar beet

Beta vulgaris

ddc:570

rvk:WG 2100